A method of manufacturing a semiconductor device including a semiconductor layer and a dielectric layer deposited on the semiconductor layer, including: forming the semiconductor layer; performing a surface treatment for removing a residual carbon compound, on a surface of the semiconductor layer formed; forming a dielectric film under a depositing condition corresponding to a surface state after the surface treatment, on at least a part of the surface of the semiconductor layer on which the surface treatment has been performed; and changing a crystalline state of at least a partial region of the semiconductor layer by performing a heat treatment on the semiconductor layer on which the dielectric film has been formed.
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1. A method of manufacturing a semiconductor device including a semiconductor layer and a dielectric layer deposited on the semiconductor layer, the method comprising:
forming the semiconductor layer;
performing a surface treatment for removing a residual carbon compound, on a surface of the semiconductor layer formed;
forming a dielectric film following the surface treatment, under a depositing condition corresponding to a surface state after the surface treatment, on at least a part of the surface of the semiconductor layer on which the surface treatment has been performed; and
changing a crystalline state of at least a partial region of the semiconductor layer by performing a heat treatment on the semiconductor layer on which the dielectric film has been formed.
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This application is a continuation of PCT International Application No. PCT/JP2008/071151 filed on Nov. 20, 2008 which claims the benefit of priority from Japanese Patent Application No. 2007-301591 filed on Nov. 21, 2007, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a manufacturing method of a semiconductor device, a semiconductor device, a communication apparatus, and a semiconductor laser. More particularly, the invention relates to a manufacturing method of a semiconductor device that includes a semiconductor laminated structure in its structure, a semiconductor device, a communication apparatus, and a semiconductor laser.
2. Description of the Related Art
Semiconductor optical devices include optical devices that perform electricity-light conversion/light-electricity conversion, such as light emitting devices and light receiving devices, and optical devices that transmit optical signals, such as optical waveguides, optical switches, isolators, and photonic crystals.
The light emitting devices such as semiconductor lasers and light-emitting diodes, of the optical devices that perform the electricity-light conversion/light-electricity conversion, each include a semiconductor laminated structure constituted of a plurality of semiconductor layers including an active layer of a semiconductor hetero structure or a quantum well structure. These light emitting devices utilize the action of radiation recombination in the semiconductor laminated structure to perform the electricity-light conversion.
The light receiving devices each similarly include a semiconductor laminated structure constituted of a plurality of semiconductor layers. The light receiving devices each utilize the action of light absorption in a certain semiconductor layer in the semiconductor laminated structure to perform the light-electricity conversion.
The optical devices that perform the transmission of the optical signals each include, depending on their types, a semiconductor laminated structure constituted of a plurality of semiconductor layers having predetermined refractive indices (or a plurality of semiconductor layers that include a semiconductor layer having a variable refractive index by an electrooptic effect). The optical devices that perform the transmission of the optical signals each perform desired optical-signal transmission utilizing a difference between refractive indices of the plurality of semiconductor layers.
While the optical devices described above are mainly constituted of the semiconductor laminated structures, their manufacturing methods sometimes include a process for changing a physical property of a predetermined semiconductor layer in the semiconductor laminated structure.
For example, when the optical device is a semiconductor laser, a window region may be formed on an emission facet for getting laser light generated by resonating light generated by radiation recombination to the outside. The emission facet of the semiconductor laser may be degraded by high-density light absorption, and this may cause catastrophic optical damage (COD). Therefore, in the semiconductor laser formed with the window region, absorption of emitted light at the position of the emission facet is reduced by increasing the bandgap of the semiconductor of the semiconductor laminated structure at that position.
To form such a window region, for example, in a GaAs semiconductor laser, a dielectric film having an effect of promoting diffusion of Ga of a semiconductor laminated structure corresponding to the window region is formed on laminated layers of the semiconductor laminated structure, as described in Japanese Patent Application Laid-open No. H7-122816. The semiconductor laminated structure is then heat-treated, thereby disordering a predetermined semiconductor layer in the semiconductor laminated structure corresponding to the window region, and changing a physical property value of the semiconductor layer. That is, a process of increasing a bandgap is performed. This method is called an impurity free vacancy disordering (IFVD) method.
When an optical device that includes a semiconductor laminated structure in its structure is manufactured, if heat treatment is performed after forming a dielectric film on laminated layers in the semiconductor laminated structure, cracks may be generated in the heat treatment of the dielectric film formed on a surface of the laminated layers in the semiconductor laminated structure, and effects of the dielectric film may be reduced. As a result, a semiconductor surface at which the dielectric film has been formed is roughened, and if an electrode is formed on the semiconductor surface after that, there is a problem of a contact resistance being increased. Particularly, the IFVD method, to which the present invention is directed, requires a heat treatment at a temperature higher than a temperature generally used in heat treatments, to disorder a window region and achieve a bandgap of a desirable magnitude. When a device is manufactured by a conventionally used common process, the heat treatment generates cracks in the dielectric layer, and functions of the dielectric layer are prominently damaged. As a result, there has been a problem of not being able to generate a bandgap of a desirable magnitude, or the contact resistance increasing due to a roughened semiconductor-layer surface following the generation of cracks in the dielectric layer.
A method according to an aspect of the present invention for manufacturing a semiconductor device including a semiconductor layer and a dielectric layer deposited on the semiconductor layer includes: forming the semiconductor layer; performing a surface treatment for removing a residual carbon compound, on a surface of the semiconductor layer formed; forming a dielectric film under a depositing condition corresponding to a surface state after the surface treatment, on at least a part of the surface of the semiconductor layer on which the surface treatment has been performed; and changing a crystalline state of at least a partial region of the semiconductor layer by performing a heat treatment on the semiconductor layer on which the dielectric film has been formed.
A semiconductor device according to another aspect of the present invention is manufactured by the method.
A communication apparatus according to yet another aspect of the present invention uses the semiconductor device.
The above and other features, advantages, and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
The present invention is based on a discovery that by rendering a surface state of a semiconductor layer and a refractive index of a dielectric layer deposited on the semiconductor layer to have a certain relation with each other, roughening of a semiconductor layer surface by a subsequent heat treatment process can be prevented. A manufacturing method of an optical device according to an embodiment of the present invention will be explained below with reference to the drawings.
The manufacturing method of an optical device according to the embodiment of the present invention includes a step of performing a heat treatment on the semiconductor laminated structure 1, and uses a thermal action of the heat treatment, as will be explained below. Therefore, since the semiconductor materials of the semiconductor layers 2-1, and 2-2 to 2-n are of the plurality of types as stated above, each of the semiconductor layers 2-1 and 2-2 to 2-n receives a different thermal action, thereby practically achieving effects of the heat treatment.
Although the semiconductor materials are not particularly limited, a compound semiconductor constituted of a plurality of constituent atoms is preferable. This is because when the semiconductor layers 2-1 and 2-2 to 2-n are formed of compound semiconductors each constituted of a plurality of constituent atoms, bond energies of the constituent atoms of the compound semiconductors differ depending on kinds of the constituent atoms, and thus they are easily affected by the thermal actions in the heat treatment. In other words, because the bond energies of the constituent atoms of a semiconductor that constitutes a semiconductor layer are different depending on the kinds of the constituent atoms, a part of the constituent atoms moves due to the thermal action in the heat treatment, and a crystalline state of the semiconductor at that position becomes easy to change. The constituent atoms are atoms for constituting the semiconductor material itself. Of course, not only compound semiconductors, but a semiconductor material made of a single element may be used as the semiconductor layers 2-1 and 2-2 to 2-n of the semiconductor laminated structure 1, as long as crystalline states of the semiconductor materials change by movement of constituent atoms due to the thermal actions in the heat treatment.
Although the optical device is not depicted in the drawings, it may be any optical device as long as it has the semiconductor laminated structure 1 described above in its stricture. For example, the optical device may be an optical device that performs electricity-light conversion/light-electricity conversion such as a light emitting device or a light receiving device, or an optical device that transmits optical signals such as an optical waveguide, an optical switch, an isolator, or a photonic crystal. The present invention is not limited to optical devices, and may be widely applied to semiconductor devices such as a MOS diode and a MOS transistor that are semiconductor devices each having a dielectric layer formed on a semiconductor layer and that require improvement in adhesiveness thereof.
A process of manufacturing an optical device that includes the semiconductor laminated structure 1 described above in its structure is explained with reference to cross-sectional views for explaining some of the manufacturing process of the optical device, which are depicted in
First, the semiconductor laminated structure 1 depicted in
Preferably, a state after performing the surface treatment on the laminated layer surface 3 of the semiconductor laminated structure 1 is such that the laminated layer surface 3 demonstrates a hydrophilic property if it is assumed that water 6 is present on the laminated layer surface 3 of the semiconductor laminated structure 1 on which the surface treatment has been performed, as depicted in
The laminated layer surface 3 demonstrating the hydrophilic property specifically means that a contact angle θ of the water 6 on the laminated layer surface 3 with respect to the laminated layer surface 3 is equal to or smaller than 60 degrees. On the contrary, if the laminated layer surface 3 does not have a hydrophilic property, that is, if the laminated layer surface 3 has a hydrophobic property, the contact angle θ becomes equal to or larger than 90 degrees (θ becomes 60 to 90 degrees if it has an intermediate property between a hydrophilic property and a hydrophobic property). The contact angle θ may be measured by using a goniometer contact-angle measuring apparatus or the like. It is also possible to approximately distinguish by visual observation whether the contact angle is equal to or smaller than 60 degrees, or within the range of 60 to 90 degrees, or equal to or greater than 90 degrees and thus an approximate surface state may be ascertained by visually confirming the contact angle of water on the laminated layer surface in a treatment process.
As described above, in performing the surface treatment on the laminated layer surface 3 of the semiconductor laminated structure 1, preferably, the surface treatment is performed using an acidic liquid. This is because if the laminated layer surface 3 of the semiconductor laminated structure 1 comes in contact with the atmosphere and is oxidized after the semiconductor laminated structure 1 is formed as depicted in
After the surface treatment is performed on the laminated layer surface 3, as depicted in
Promoting the effect of changing the crystalline state of the semiconductor layer means to promote movement of constituent atoms of the semiconductor layers 2-1 and 2-2 to 2-n that constitute the semiconductor laminated structure 1 due to the thermal actions by the heat treatment or movement of holes corresponding to the moved atoms, for example. More specifically, if the dielectric film 4 has the effect of absorbing the moving constituent atoms of the semiconductor layers 2-1 and 2-2 to 2-n or the moving holes, the effect of changing the crystalline state of the semiconductor layer is promoted.
As depicted in
Next, the heat treatment is performed on the semiconductor laminated structure 1 having the dielectric film 4 formed at the predetermined position on the laminated layer surface 3 (ST4 in
When the thermal treatment is performed on the semiconductor laminated structure 1, if the dielectric film 4 has the function of promoting the change in the crystalline state of the semiconductor layer, the crystalline state changes in the at least the partial region in the at least one layer of the semiconductor laminated structure 1 in the region (the region 5a in
After the heat treatment is finished, other necessary treatments are performed on the semiconductor laminated structure 1 (ST5 in
For example, if the optical device is a light emitting device or a light receiving device, these treatments include etching of physically processing the semiconductor laminated structure 1, forming a passivation film, forming an electrode, and forming a reflection film, to complete the light emitting device or the light receiving device. If the optical device is an optical waveguide, an optical switch, an isolator, or a photonic crystal, these treatments include etching of physically processing the semiconductor laminated structure 1, forming a passivation film, and forming a necessary electrode, to complete the optical waveguide, the optical switch, the isolator, or the photonic crystal.
The manufacturing method of an optical device according to an embodiment of the present invention is explained below by exemplifying a more specific manufacturing method of an optical device.
The semiconductor laser element 10 further includes two cleavage surfaces at both ends in a longitudinal direction of the ridge 17, by the semiconductor substrate 14 integrated with the semiconductor laminated structure 11 being cleaved. On one of the two cleavage surfaces, a low reflection film 19 is formed to output laser light 18, generated by resonating light generated within the active layer in the semiconductor laminated structure 1 by using the two cleavage surfaces as reflection mirrors, from an emission region 15 of the semiconductor laser element 10 to the outside. On the other cleavage surface, a high reflection film 20 is formed to efficiently output the generated laser light 18 to the outside of the semiconductor laser element 10 from only a low-reflection film 19 end.
The active layer 12-4 forms a quantum well structure constituted of a lower barrier layer 12-4a made of AlGaAs (with an Al composition of 30%), a quantum well layer 12-4b made of InGaAs, and an upper barrier layer 12-4c made of AlGaAs (with an Al composition of 30%), in the order from the lower layer. The quantum well structure may not only be a single-quantum well structure, but instead may be a multi-quantum well structure.
In the semiconductor laser element 10, the ridge 17 is formed by physically processing a part of an upper part of the semiconductor laminated structure 11 to limit a region through which a current is flown into the active layer 12-4. That is, a part of the p-cladding layer 12-6 at an upper side of the semiconductor laminated structure 11 and the p-contact layer 12-7 are physically processed to form the processed portion in a shape of the ridge 17.
The semiconductor laser element 10, to flow the current from the outside into the active layer 12-4, an upper electrode 22 is formed at a p-contact layer 12-7 surface side and a lower electrode 23 is formed on a back surface of the GaAs semiconductor substrate 14. The upper electrode 22 is formed via an insulation layer 21, on a surface of the semiconductor laminated structure 11 other than the top of the ridge 17, to be able to flow the current from only the top of the ridge 17 in flowing the current from the outside.
As described above, the current flown from the upper electrode 22 and the lower electrode 23 is concentrated at a part of the active layer 12-4, due to the ridge 17 formed by having a part of the semiconductor laminated structure 11 processed, and the laser light 18 is output to the outside of the semiconductor laser element 10. However, because the laser light 18 emitted from the emission region 15 (see
In the region 15a that becomes a window region, a group-III atom in the GaAs compound semiconductor layer described above that constitutes the semiconductor laminated structure 11 is diffused, and a state of including a mixed crystal occurs. Consequently, a crystalline state of the semiconductor layer that constitutes the semiconductor laminated structure 11 in the region 15a is changed.
A process of manufacturing the semiconductor laser element 10 having the above structure is explained with reference to the drawings. First, as depicted in
To provide a predetermined semiconductor layer with conductivity in epitaxially growing the semiconductor laminated structure 11, doping of Si is performed during the epitaxial growth of the n-buffer layer 12-1 and the n-cladding layer 12-2 and doping of C is performed during the epitaxial growth of the p-cladding layer 12-6 and the p-contact layer 12-7.
After the semiconductor laminated structure 11 is epitaxially grown on the semiconductor substrate 14, the semiconductor substrate 14 is taken out from the MOCVD device, and a surface treatment is performed on a laminated layer surface 30 of the semiconductor laminated structure 11. For the surface treatment in the present example, a surface cleaning process was performed for 90 seconds on the laminated layer surface 30 of the semiconductor laminated structure 11 by using an undiluted solution of concentrated sulfuric acid (equal to or greater than 95%) manufactured by Wako Pure Chemical Industries, Ltd. Thereafter, cleaning by deionized water was performed for five minutes.
After the surface treatment was performed, a test of dropping water on the laminated layer surface 30 was performed to check a surface state of the laminated layer surface 30 after the surface treatment. As a result of the test, when the surface treatment using the concentrated sulfuric acid was performed, as water 16 was dropped on the laminated layer surface 30, the contact angle θ of the water 16 was about 60 degrees indicating hydrophilicity, as depicted in
As described above, while a treatment using a concentrated sulfuric acid has been disclosed as a preferable example in the present example, any method that allows reduction of a residual component of a surface carbon compound to a substantially negligible amount may be used as the surface cleaning treatment according to the present invention. For example, a surface treatment may be performed by using a sulfuric acid etchant (sulfuric acid:hydrogen peroxide:water=3:1:50).
After the test was finished, a dielectric film 40 and a dielectric film 40′ which were made of SiN and had refractive indices of 1.9 and 2.1 respectively were formed by using a CVD device on the laminated layer surface 30 corresponding to the regions 15a and the region 15b of the semiconductor laminated structure 11 as depicted in
After the dielectric film 40 and the dielectric film 40′ are formed on the laminated layer surface 30, a heat treatment is performed on the semiconductor laminated structure 11. In the present example, a device to perform the heat treatment is a rapid thermal annealing (RTA) device. The heat treatment is performed under conditions of the temperature being 900° C. and the treatment time period being 30 seconds.
By performing the heat treatment, the crystalline state of at least a partial region in at least one layer of the semiconductor laminated structure 11 in the region 15a in which the dielectric film 40 has been formed changes as depicted in
After the heat treatment was performed, a surface state of the laminated layer surface 30 was tested. First, to illustrate comparison with respect to a conventional surface cleaning treatment, results of an Auger analysis of a sample having a dielectric layer deposited on a semiconductor surface cleaned by a cleaning method according to the present invention are depicted in
Further, surface states of the laminated layer surfaces 30 after the heat treatments were tested for the samples having the dielectric films 40′ made of SiN with their refractive indices varied between 2 and 2.2 formed on the laminated layer surfaces 30, which were manufactured by changing the depositing conditions for comparison.
That is, a surface state after the surface treatment relates to adhesiveness between the laminated layer surface 30 of the semiconductor laminated structure 11 and the dielectric film, and a refractive index of the dielectric film relates to a density of a dielectric substance that constitutes the dielectric film. The density of the dielectric substance relates to a stress given to the laminated layer surface 30 on which the dielectric film is formed. Therefore, if the refractive index of the dielectric film is equal to or less than a predetermined value corresponding to a surface state of the laminated layer surface 30, upon formation of the dielectric film on the laminated layer surface 30 of the semiconductor laminated structure 11, a stress working between the dielectric film and the semiconductor layer in the laminated layer surface 30 becomes optimum. Consequently, surface roughening does not occur after the heat treatment. In other words, not being limited to the above described materials, a relationship similar to that depicted in
In the present example, the heat treatment temperature was 900° C. Samples subjected to heat treatments at different temperatures were also manufactured, and increases in bandgaps of semiconductor layers corresponding to window regions were measured.
After the heat treatment was finished, other necessary processes to complete the semiconductor laser element 10 were performed. A position corresponding to the top of the ridge 17 on the laminated layer surface 30 of the semiconductor laminated structure 11 is masked by performing lithography. After the masking, as depicted in
After the ridge 17 is formed, the insulation layer 21 made of SiN is formed by using a CVD device on an exposed surface of the semiconductor laminated structure 11. As depicted in
Finally,
As explained above, according to the present invention, prominent effects are obtained, such that adhesiveness between a semiconductor layer and a dielectric layer is improved, surface roughening (peeling off) of the dielectric film does not occur, effects of the dielectric layer (promotion of disordering in a window region and suppression of disordering in a non-window region) are sufficiently demonstrated, and a contact resistance is not increased.
According to an embodiment of the present invention, prominent effects of being able to perform a process including a heat treatment appropriately and effects of a dielectric film used not being degraded are demonstrated.
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
Taniguchi, Hidehiro, Namegaya, Takeshi, Katayama, Etsuji
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